Indoles synthesis, palladium® bromide

Dialkylindolines and 1,3-dialkylindoles are formed in poor yield (<10%) from the reaction of ethyl- or phenymagnesium bromide with 2-chloro-N-methyl-N-allylaniline in the presence of catalytic quantities of (bistriphenylphosphine)nickel dichloride.72 In a modification of this procedure, the allyl derivatives can be converted by stoichiometric amounts of tetrakis(triphenylphosphine)nickel into 1,3-dialkylindoles in moderate yield72 (Scheme 43) an initial process of oxidative addition and ensuing cyclization of arylnickel intermediates is thought to occur. In contrast to the nickel system,72 it has proved possible to achieve the indole synthesis by means of catalytic quantities of palladium acetate.73 It is preferable to use... 

Knochel demonstrated the effectiveness of soluble potassium or cesium alkoxides such as KO Bu or CsO Bu as well as KH in iV-methylpyrrolidinone (NMP) for promoting the 5-endo-dig cyclizations of 2-alkynylanilines to 2-substituted indoles in solution or the solid-phase <00AG(E)2488>. Alternatively, Cacchi coupled a palladium-catalyzed cyclization of o-alkynyltrifluoroacetanilides with the addition of benzyl bromide or ethyl iodoacetate to afford 2-substituted-3-benzyl or 3-indolylcarboxylate esters, respectively <00SL394>. Yamamoto reported a new palladium catalyzed indole synthesis in which 2-(l-alkynyl)-Ar-alkylideneanilines 117 give 2-substituted-3-(l-alkenyl)indoles 118 directly from the imine by the in situ coupling of an aldehyde with the alkynylaniline <00JA5662>. 

Azoles can be produced from products of palladium-catalyzed hydrazone arylation and can serve as substrates for arylation reactions to produce N-aryl azoles. The Fischer indole synthesis uses N-ary I hydrazones, and these hydrazones can be generated by palladium-catalyzed chemistry. Benzophenone hydrazone was found by both the Yale and MIT groups to be a particularly effective substrate for palladium-catalyzed reactions, as summarized in Eq. (24) [140,141]. Reactions of benzophenone hydrazone with either aryl bromides or iodides occur in high yields using either DPPF- or BINAP-ligated palladium. These reactions are general and occur with electron-rich, electron-poor, hindered or unhindered aryl halides. The products of these reactions can be converted to hydrazones that bear enolizable hydrogens and are suitable for indole synthesis in the presence of acid and ketone [140]. 

The cyclization of IV-allyl-o-haloanilines was adapted to the solid phase for both indoles [332, 333] and oxindoles [334]. For example, as illustrated below, a library of l-acyl-3-aIkyl-6-hydroxyindoles is readily assembled from acid chlorides, allylic bromides, and 4-bromo-3-nitroanisole [332], Zhang and Maryanoff used the Rink amide resin to prepare Af-benzylindole-3-acetamides and related indoles via Heck cyclization [333], and Balasubramanian employed this technology to the synthesis of oxindoles via the palladium cyclization of o-iodo-N-acryloylanilines [334], This latter cyclization route to oxindoles is presented later in this section. 

Ishikura et al. reported the total synthesis of ellipticine (228) starting from N-Boc indole (1256) and the vinyl bromide 1258 (719-721). This methodology involves a palladium-catalyzed, tandem cyclization-cross-coupling reaction of the indolyl borate 1257 with the vinyl bromide 1258 as the key step. Using a literature procedure, the vinyl bromide 1258 was prepared as an E/Z mixture starting from CIS- and trans-crotyl alcohol. The indolyl borate 1257 was generated in situ from... 

In 1976, Hegedus et al. described the synthesis of indoles using a Pd-assisted intramolecular amination of olefins, which tolerated a range of functionalities [8a, 114]. For example, the requisite o-allylaniline 119 was prepared in high yield by the reaction of 5-methoxy-carbonyl-2-bromoaniline with n-ally I nickel bromide. Addition of 119 to a suspension of stoichiometric PdCl2(CH3CN)2 in THF produced a yellow precipitate (the putative intermediate 121), which upon treatment with Et, N gave rise to indole 120 and deposited metallic palladium. 

Early examples of the total synthesis of naturally occurring indole alkaloids employing the Suzuki reaction include ellipticine (10) as repotted by Miller et al. [34], The aryl bromide, 6-amino-7-bromo-5,8-dimethylisoquinoline (45) was derived from 2,5-dimethylanilinc in nine steps. The Suzuki coupling of 45 with phenylboronic acid was carried out using catalytic tetrakis(triphenylphosphine)palladium in benzene and with Na,CO, serving as the base to furnish... 

With the development of Buchwald-Hartwig amination reactions, the amine component of these indoles can also be introduced into these precursors via palladium catalysis [8]. As shown by Ackermann, this can be coupled with aryl halide alkynylation and cyclization to provide a one-pot, three-component synthesis of substituted indoles (Scheme 6.6) [9]. In this case, simple ortho-dihaloarene derivatives S were employed as starting materials, with Sonogashira coupling occurring at the more activated aryl-iodide bond, followed by selective coupling of various alkyl or arylamines. Alternatively, Zhao has recently demonstrated that amination can be performed on both bromoalkyne 6, followed by the aryl-bromide bond, to provide a route to 2-amidoindoles (Scheme 6.7) [10]. 

This type of cyclization reaction was applied in the synthesis of p-carbo-linones and total synthesis of dipyrrolobenzoquinone ( )-terreusinone as well. In 2005, Barluenga and co-workers reported a novel approach for the synthesis of indoles from o-bromoanilines and alkenyl halides via a palladium-catalyzed cascade process (Scheme 2.112). The reaction involves an alkenyl amination followed by an intramolecular Heck reaction. As the authors demonstrated, this process represents the first example of the participation of alkenyl amination reactions in Pd-catalyzed cascade reactions. Initially, the relative reactivity of aiyl and alkenyl bromides and chlorides towards Pd-catalyzed amination was investigated. Competition... 

In contrast to the alkynylation of acidic C-H bonds which can also be achieved using alkynyliodonium salts, the direct C-H functionalization of aromatic compounds or olefins has never been realized with this class of reagents so far. However, after several unsuccessful attempts using palladium or copper catalysts and alkynyliodonium salts for the alkynylation of heterocycles, Waser and Brand reported in 2009 the first efficient alkynylation of indoles using TIPS-EBX 52 and AuCl as catalyst (Scheme 18) [117]. With indole, selective C3-aIkynylation was obtained. The reaction was tolerant to many functional groups such as bromides, acids, or alcohols. The method was already used in the synthesis of starting materials for Friedel-Crafts reactions of aminocyclopropanes [118] and for hydroamidation to access indole c -enamides [119]. In 2010, Nevado and de Haro demonstrated that alkynylation was also possible using directly terminal propiolic ester derivatives and (diacetoxyiodo)benzene as co-oxidant [120]. 

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